CN116358277B

CN116358277B - Online drying device of feed processing

Info

Publication number: CN116358277B
Application number: CN202310626541.4A
Authority: CN
Inventors: 胡建新; 刘晓; 张有洋; 乔常巍; 马艳伟; 张平; 程胜杰; 姚利双; 李森; 姜焰; 范保磊; 禹青娇; 曹恒建; 高文岐; 薛洋
Original assignee: Dezhou Hejia Machinery Equipment Co ltd
Current assignee: Dezhou Hejia Machinery Equipment Co ltd
Priority date: 2023-05-31
Filing date: 2023-05-31
Publication date: 2023-08-08
Anticipated expiration: 2043-05-31
Also published as: CN116358277A

Abstract

The invention relates to the field of drying, in particular to an online drying device for feed processing. The material conveying device comprises a feeding mechanism and a drying mechanism, wherein the drying mechanism comprises a drying chamber, a plurality of conveying chain plates are arranged in the drying chamber, the conveying chain plates are arranged at intervals up and down and are inclined, the inclination directions of two adjacent conveying chain plates are opposite, the collision force is enhanced when materials fall from the upper conveying chain plate to the lower conveying chain plate, the materials can fall and disperse sufficiently, and then the materials can be dried more uniformly; further, the air outlet cavity is formed in one end, between two adjacent conveying chain plates, of the large distance, hot air can be prevented from escaping from the other end because the other ends of the two adjacent conveying chain plates are close to each other, meanwhile, hot air blown out of the air outlet cavity can blow materials with smaller humidity to the discharge end of the corresponding conveying chain plate, dry and wet materials are separated, drying stroke of the dry materials is reduced, excessive drying of the dry materials is prevented, and drying uniformity is further improved.

Description

Online drying device of feed processing

Technical Field

The invention relates to the field of drying, in particular to an online drying device for feed processing.

Background

In the course of feed processing, the material needs to be dried. A multi-layer mesh belt type dryer is a common drying apparatus which dries a material distributed on a multi-layer conveyor mesh belt using hot air flowing from bottom to top. The chinese patent publication No. CN 205718342U discloses a multi-layered mesh belt type circulation dryer in which each layer of mesh belt is independently operated, and a drying stroke is adjusted by adjusting an operation speed of each layer of mesh belt to ensure a drying effect. But multilayer guipure formula drying-machine is in the use, and the conveyer belt material loading easily leads to the uneven thickness of material layer on, and the time of just drying through whole adjustment can make thin material layer "overdrying", and thick material layer is dry inadequately, and the material is heated unevenly, finally leads to drying efficiency low, stoving effect is poor.

Disclosure of Invention

According to the defects of the prior art, the invention provides an online drying device for feed processing, which aims to solve the problems of low drying efficiency and poor drying effect of the existing drying device.

The invention relates to an on-line drying device for feed processing, which adopts the following technical scheme: the material conveying device comprises a feeding mechanism and a drying mechanism, wherein the feeding mechanism is used for conveying materials to the drying mechanism, the drying mechanism comprises a drying chamber, a plurality of conveying chain plates are arranged in the drying chamber in a ring shape and can be rotatably arranged in the drying chamber, the conveying chain plates are arranged at intervals up and down and are inclined, the inclination directions of two adjacent conveying chain plates are opposite, the rotation directions of all conveying chain plates are configured to convey the materials from the lower end to the higher end of the conveying chain plate, the materials from the feeding mechanism enter from the lower end of the conveying chain plate at the uppermost layer and fall from the higher end of the conveying chain plate at the uppermost layer to the lower end of the conveying chain plate at the next layer, and finally the materials are discharged from the higher end of the conveying chain plate at the lowermost layer; one end with a large distance between two adjacent conveying chain plates is provided with an air outlet cavity, and the air outlet cavity can blow hot air to materials falling from the upper layer.

Optionally, the inclination angle of the conveying flight is set to 5 degrees to 8 degrees.

Optionally, the air outlet cavity at the lowest part is connected with a hot air mechanism, an air suction pipe is arranged in the annular space of each conveying chain plate, one end of the air suction pipe is connected with an air pump, the air pump on the air suction pipe at the next stage is communicated with the air outlet cavity at the upper stage, the air pump on the air suction pipe at the highest part is communicated with an exhaust hole, the exhaust hole is communicated with the outside, and the air pump can suck hot air blown out by the hot air mechanism through the air suction pipe and discharge the hot air from the corresponding air outlet cavity or the exhaust hole.

Optionally, the air inlet of the air suction pipe is arranged at the upper end of the air suction pipe, and the size of the air inlet is matched with the length of the air suction pipe.

Optionally, except the conveying chain plate at the lowest layer, a baffle plate extending vertically is arranged at a pre-position in front of the blanking end of the rest conveying chain plates along the conveying direction of the materials.

Optionally, a vertically extending wind deflector is provided at the end of the smaller distance between two adjacent conveying chain plates.

Optionally, the feeding mechanism comprises a supporting shell, a feeding groove is formed in the upper end of the supporting shell, a conveyor belt is arranged in the supporting shell, and the conveyor belt receives materials of the feeding groove and conveys the materials to the uppermost conveying chain plate.

Optionally, the feeding mechanism further comprises a distributor, and the distributor is used for intermittently throwing the materials from the feeding chute to the conveyor belt.

Optionally, the distributor comprises a mandrel and a distributing plate arranged on the mandrel, the distributing plate is uniformly distributed along the circumferential direction of the mandrel, a distributing motor is arranged on the supporting shell, and the distributing motor is used for driving the mandrel to rotate.

Optionally, a material guiding plate is arranged at the material feeding end of the uppermost conveying chain plate, and a material discharging plate is arranged at the material discharging end of the lowermost conveying chain plate.

The beneficial effects of the invention are as follows: according to the feed processing online drying device, the plurality of inclined conveying chain plates are arranged, the inclination directions of the adjacent conveying chain plates are opposite, the collision force is enhanced when materials fall from the upper layer of conveying chain plates to the lower layer of conveying chain plates, the materials can fall and disperse sufficiently, and the materials can be dried more uniformly; further, the air outlet cavity is formed in one end, which is large in distance between two adjacent conveying chain plates, of the air outlet cavity, namely, the air outlet cavity is formed in the material falling end, and because the other ends of the two adjacent conveying chain plates are close to each other, hot air can be prevented from escaping from the other ends, meanwhile, hot air blown out of the air outlet cavity can blow materials with smaller humidity to the discharge ends of the corresponding conveying chain plates, dry and wet materials are separated, drying stroke of the dry materials is reduced, excessive drying of the dry materials is prevented, and drying uniformity is further improved.

Further, the air outlet cavity at the lowest part is connected with a hot air mechanism, an air suction pipe is arranged in the annular space of each conveying chain plate, the air suction pipe at the next stage is communicated with the air outlet cavity at the previous stage through an air pump, when the material is dried, the hot air mechanism supplies hot air for the air outlet cavity at the lowest part, and under the action of the air pump corresponding to the air suction pipe at the lowest part, the hot air blown out from the air outlet cavity at the lowest part enters the air suction pipe through the conveying chain plate at the lowest part and is blown out from the air outlet cavity at the previous stage, so that the circulation is realized. According to the invention, under the general trend of air outlet above the lower air inlet, hot air can pass through the conveying chain plate from top to bottom and enter the air suction pipe for each layer of conveying chain plate, so that the dried materials are prevented from being wetted again, the working efficiency is improved, and the drying effect is ensured.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions of the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art, it being understood that these drawings are not necessarily drawn to scale.

FIG. 1 is a schematic diagram of the overall structure of an on-line drying device for feed processing according to the present invention;

FIG. 2 is a front view of an on-line drying apparatus for feed processing according to the present invention;

FIG. 3 is a top view of an on-line dryer for feed processing according to the present invention;

FIG. 4 is a cross-sectional view A-A of FIG. 3;

FIG. 5 is a rear view of an on-line dryer for feed processing according to the present invention;

fig. 6 is a schematic structural view of an air suction pipe in the present invention.

In the figure: 100. a feeding structure; 101. a feed chute; 102. a distributor; 103. a material distributing motor; 104. a conveyor belt; 105. a support case; 200. a drying mechanism; 201. a first motor; 202. a second motor; 203. a third motor; 204. a first drive shaft; 205. a second drive shaft; 206. a third drive shaft; 207. a first driven shaft; 208. a second driven shaft; 209. a third driven shaft; 210. a conveying chain plate; 211. a drying chamber; 212. maintaining the door; 213. an air suction pipe; 214. an air outlet cavity; 215. a material guide plate; 216. a discharge plate; 217. connecting an air pipe; 218. an air pump; 219. an exhaust hole; 220. a wind deflector; 221. a hot air mechanism; 222. and a striker plate.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1 to 6, an on-line drying apparatus for feed processing according to the present invention includes a feeding mechanism 100 and a drying mechanism 200, wherein the feeding mechanism 100 is used for conveying materials to the drying mechanism 200. The drying mechanism 200 includes a drying chamber 211, a plurality of conveying chain plates 210 are disposed in the drying chamber 211, the plurality of conveying chain plates 210 are annular and can be rotatably disposed in the drying chamber 211, the plurality of conveying chain plates 210 are disposed at intervals up and down and are inclined, the inclination directions of two adjacent conveying chain plates 210 are opposite, the rotation directions of all conveying chain plates 210 are configured to convey materials from the lower end to the higher end of the conveying chain plate 210, the materials from the feeding mechanism 100 enter from the lower end of the conveying chain plate 210 at the uppermost layer and fall from the higher end of the conveying chain plate 210 at the uppermost layer to the lower end of the conveying chain plate 210 at the next layer, and finally are discharged from the higher end of the conveying chain plate 210 at the lowermost layer.

An air outlet cavity 214 is arranged at one end with a large distance between two adjacent conveying chain plates 210, and the air outlet cavity 214 can blow hot air to the material falling from the previous layer, so that the material is dried. It can be understood that the plurality of conveying chain plates 210 are obliquely arranged, so that the distance between the blanking end of the upper conveying chain plate 210 and the feeding end of the lower conveying chain plate 210 in the vertical direction is increased, the collision force is enhanced when the material falls from the upper conveying chain plate 210 to the lower conveying chain plate 210, the material can be sufficiently dropped and dispersed, and further the material can be dried more uniformly; further, the air outlet cavity 214 is formed at the material falling end, because the other ends of the two adjacent conveying chain plates 210 are close to each other, hot air can be prevented from escaping from the other ends, meanwhile, the hot air blown out from the air outlet cavity 214 can blow the material with smaller humidity to the discharge end of the corresponding conveying chain plate 210, so that dry and wet materials are separated, the drying stroke of the dry materials is reduced, excessive drying of the dry materials is prevented, and the drying uniformity is further improved.

It can be understood that, in order to realize the rotary feeding of the conveying chain plate 210, a plurality of driving shafts and a plurality of driven shafts are rotatably disposed in the drying chamber 211, one driving shaft and one driven shaft are correspondingly formed into a group, the conveying chain plate 210 is wound around the corresponding driving shaft and driven shaft, and each driving shaft is driven to rotate by a driving motor.

In this embodiment, a hot air mechanism 221 may be connected to each air outlet cavity 214, the hot air mechanism 221 provides hot air for the air outlet cavities 214, and the blowing force of the air outlet cavities 214 may be changed by adjusting the parameters of the hot air mechanism 221.

In a further embodiment, because the conveying chain plates 210 are obliquely arranged, and in combination with the conveying distance of the conveying chain plates 210, a smaller inclination angle can enable one end, away from each other, of each adjacent conveying chain plate 210 to have a larger interval in the vertical direction, so that in order to facilitate conveying of materials by the conveying chain plates 210, the inclination angle of the conveying chain plates 210 is set to be 5-8 degrees, and the inclination angle of the conveying chain plates 210 is preferably 5 degrees.

In a further embodiment, the lowest air outlet chamber 214 is connected to a hot air mechanism 221, an air suction pipe 213 is disposed in the annular space of each conveying chain plate 210, one end of the air suction pipe 213 is connected to an air pump 218, the air pump 218 on the air suction pipe 213 of the next stage is communicated with the air outlet chamber 214 of the previous stage, the air pump 218 on the air suction pipe 213 of the highest stage is communicated with an air exhaust hole 219, the air exhaust hole 219 is communicated with the outside, and the air pump 218 can suck hot air blown by the hot air mechanism 221 through the air suction pipe 213 and exhaust the hot air from the corresponding air outlet chamber 214 or the air exhaust hole 219. When the material is dried, the hot air mechanism 221 supplies hot air to the lowest air outlet cavity 214, and under the action of the air pump 218 corresponding to the lowest air suction pipe 213, the hot air blown out from the lowest air outlet cavity 214 enters the air suction pipe 213 through the lowest conveying chain plate 210 and is blown out from the upper air outlet cavity 214, so that the hot air sucked by the highest air suction pipe 213 is finally discharged from the air discharge hole 219. Because the dry materials after dry and wet separation can be paved above the wet materials in front, under the general trend of air inlet below and air outlet above, hot air can pass through the conveying chain plate 210 from top to bottom for each layer of conveying chain plate 210 to enter the air suction pipe 213, so that the dried materials are prevented from being wetted again, the working efficiency is improved, and the drying effect is ensured.

In this embodiment, to ensure the air suction effect of the air suction pipe 213, the air inlet of the air suction pipe 213 is disposed at the upper end of the air suction pipe 213, and the size of the air inlet is adapted to the length of the air suction pipe 213. Further, as shown in fig. 6, the air suction pipe 213 may be formed by connecting a plurality of air suction branch pipes in a longitudinal and transverse manner, and the size of the conveying chain plate 210 is adapted, and the air inlet amount of the air suction pipe 213 is increased as much as possible.

In this embodiment, in order to facilitate the installation of the air suction pipes 213, the air outlet of each air suction pipe 213 is connected with a connecting air pipe 217, the connecting air pipe 217 is installed on the side wall of the drying chamber 211, and the connecting air pipe 217 is connected with a corresponding air pump 218. In order to facilitate assembly, the connecting air pipe 217 and the air pump 218 are arranged on the outer side wall of the drying chamber 211, and meanwhile, the connecting air pipe 217 can be wrapped with heat insulation cotton to prevent heat dissipation of hot air.

In a further embodiment, as shown in fig. 4, except for the lowest conveying chain plate 210, a baffle plate 222 is disposed at a pre-position in front of the blanking end of the remaining conveying chain plates 210 along the conveying direction of the material, the baffle plate 222 is vertically disposed and mounted on the inner sidewall of the drying chamber 211, and the baffle plate 222 is used for guiding the material to fall from the upper conveying chain plate 210 to the lower conveying chain plate 210.

Further, a wind guard 220 is disposed at one end of the small distance between two adjacent conveying chain plates 210, the wind guard 220 is vertically disposed and mounted on the inner sidewall of the drying chamber 211, and the wind guard 220 is used for blocking the wind blown out from the air outlet cavity 214 to escape, so as to further improve the drying effect.

In a further embodiment, the feeding mechanism 100 comprises a support housing 105, the upper end of the support housing 105 is provided with a feed chute 101, the inside of the support housing 105 is provided with a conveyor belt 104, and the conveyor belt 104 receives the material of the feed chute 101 and conveys it to the uppermost conveying flight 210.

The feeding mechanism 100 further comprises a distributor 102, the distributor 102 is used for intermittently feeding materials from the feeding chute 101 to the conveyor belt 104, the distributor 102 comprises a mandrel and distributing plates arranged on the mandrel, the distributing plates are uniformly distributed along the circumferential direction of the mandrel, a distributing motor 103 is arranged on the supporting shell 105, and the distributing motor 103 is used for driving the mandrel to rotate. In this embodiment, for easy installation, the material distributing motor 103 is connected with the mandrel through belt transmission or chain transmission, and in other embodiments, the material distributing motor 103 may also be directly connected with the mandrel through a coupling. In operation, material is fed from the feed chute 101 and is separated by the distributor 102 and then reaches the conveyor 104, the conveyor 104 conveys the material to the uppermost conveying chain plate 210, the material is dried in the drying chamber 211 by conveying the material through the multi-stage conveying chain plates 210, and finally the material is discharged from the discharging end of the lowermost conveying chain plate 210 to the drying chamber 211.

In a further embodiment, the feed end of the uppermost conveyor flight 210 is provided with a guide plate 215, the guide plate 215 being used to guide material from the feeding mechanism 100 to the uppermost conveyor flight 210.

The discharge end of the lowermost conveyor chain 210 is provided with a discharge plate 216, and the discharge plate 216 is used for guiding the material on the lowermost conveyor chain 210 out of the drying chamber 211.

In a further embodiment, the drying chamber 211 is provided with a maintenance door 212, and the maintenance door 212 is provided to facilitate inspection and maintenance of components in the drying chamber 211.

In a further embodiment, as shown in fig. 2 and 4, three conveying chain plates 210 are preferably provided, a driving shaft and a driven shaft corresponding to the conveying chain plate 210 located above are named as a first driving shaft 204 and a first driven shaft 207, a driving shaft and a driven shaft corresponding to the conveying chain plate 210 located in the middle are named as a second driving shaft 205 and a second driven shaft 208, a driving shaft and a driven shaft corresponding to the conveying chain plate 210 located below are named as a third driving shaft 206 and a third driven shaft 209, a driving motor driving the first driving shaft 204 to rotate is named as a first motor 201, a driving motor driving the second driving shaft 205 to rotate is named as a second motor 202, a driving motor driving the third driving shaft 206 to rotate is named as a third motor 203, materials are moved from the uppermost conveying chain plate 210 to the lowermost conveying chain plate 210 in a drying chamber 211, and discharged out of the drying chamber 211 after three-stage conveying drying, and naturally, the number of the conveying chain plates 210 can be two, four or other driving motors according to actual needs.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims

1. An online drying device of feed processing, its characterized in that: the material conveying device comprises a feeding mechanism and a drying mechanism, wherein the feeding mechanism is used for conveying materials to the drying mechanism, the drying mechanism comprises a drying chamber, a plurality of conveying chain plates are arranged in the drying chamber in a ring shape and can be rotatably arranged in the drying chamber, the conveying chain plates are arranged at intervals up and down and are inclined, the inclination directions of two adjacent conveying chain plates are opposite, the rotation directions of all conveying chain plates are configured to convey the materials from the lower end to the higher end of the conveying chain plate, the materials from the feeding mechanism enter from the lower end of the conveying chain plate at the uppermost layer and fall from the higher end of the conveying chain plate at the uppermost layer to the lower end of the conveying chain plate at the next layer, and finally the materials are discharged from the higher end of the conveying chain plate at the lowermost layer; one end that distance is big between two adjacent transport link joint is provided with the air-out chamber, the air-out chamber can blow hot-blast to the material that falls from last layer, a hot-blast mechanism is connected to the air-out chamber of below, the annular space inside of every transport link joint all is provided with an breathing pipe, the one end of breathing pipe is connected with the air pump, the air pump on the next grade breathing pipe communicates the air-out chamber of last level, the air pump on the top breathing pipe communicates there is the exhaust hole, exhaust hole and external intercommunication, the air pump can inhale and follow corresponding air-out chamber or exhaust hole with the hot-blast of hot-blast mechanism blowout through the breathing pipe.

2. The on-line drying device for feed processing according to claim 1, wherein: the inclination angle of the conveying chain plate is set to be 5 degrees to 8 degrees.

3. The on-line drying device for feed processing according to claim 1, wherein: the air inlet of the air suction pipe is arranged at the upper end of the air suction pipe, and the size of the air inlet is matched with the length of the air suction pipe.

4. The on-line drying device for feed processing according to claim 1, wherein: except the conveying chain plate at the lowest layer, baffle plates extending vertically are arranged at the pre-position in front of blanking ends of the other conveying chain plates along the conveying direction of materials.

5. The on-line drying device for feed processing according to claim 1, wherein: one end of the small distance between two adjacent conveying chain plates is provided with a vertically extending wind shield.

6. The on-line drying device for feed processing according to claim 1, wherein: the feeding mechanism comprises a supporting shell, the upper end of the supporting shell is provided with a feeding chute, a conveyor belt is arranged in the supporting shell, and the conveyor belt receives materials of the feeding chute and conveys the materials to the uppermost conveying chain plate.

7. The on-line drying device for feed processing of claim 6, wherein: the feeding mechanism further comprises a distributor, and the distributor is used for intermittently throwing materials from the feed chute to the conveyor belt.

8. The on-line drying device for feed processing of claim 7, wherein: the distributor comprises a mandrel and a distributing plate arranged on the mandrel, the distributing plate is uniformly distributed along the circumferential direction of the mandrel, a distributing motor is arranged on the supporting shell, and the distributing motor is used for driving the mandrel to rotate.

9. The on-line drying device for feed processing according to claim 1, wherein: the feeding end of the uppermost conveying chain plate is provided with a guide plate, and the discharging end of the lowermost conveying chain plate is provided with a discharging plate.